Carboxylic ester hydrolases in the thyroid gland of the guinea-pig. A light microscopic study

Synopsis The location of cholinesterase and non-specific esterase in the thyroid gland of the guinea-pig was studied with the light microscope. It was found that the inxodyl method for non-specific esterase activity under special conditions is superior to the cholinesterase method in a number of respects for the demonstration of the intra-, inter-and parafollicular cells. When using the indoxyl method the incubation period can be reduced from 2.5–3 hr to 40–50 min. Further, the reaction can be followed during the incubation. False localization of the reaction products is avoided, and nerves and erythrocytes are not stained.By varying the fixation time and the time of storage in gum arabic-sucrose, it was found that the miscellaneous activity of non-specific esterase in APUD cells (C-cells) and follicle cells may be due to both factors. In fresh tissue the activity of the enzyme was equal in follicle and C cells.Special cyst-like structures containing an esterase which is NaF-resistant whenn-naphthyl acetate is employed as a substrate and which gives a strong reaction at low pH values when 5-bromo indoxyl acetate is the substrate, are described, and their nature and possible origin are discussed.     

Unsuitability of indoxyl acetate as a substrate for the assay of testicular hyaluronidase

The most recently published method for the assay of testicular hyaluronidase preparations was based on the premise that the enzyme also exhibited carboxylesterase activity towards indoxyl acetate. Studies on the relative enzyme activities of various hyaluronidase preparations towards hyaluronate and indoxyl acetate, the relative stabilities towards pH, temperature and mechanical shaking and the behaviour towards a variety of inhibitors, showed that the activities towards the two substrates reflected the presence of at least two different enzyme systems in the preparations. Gel chromatography and polyacrylamide-gel-electrophoresis experiments confirmed these conclusions and the collective findings clearly establish that methods based on the use of indoxyl acetate cannot be employed to measure testicular hyaluronidase activity.     

Model film studies in enzyme histochemistry with special reference to glucose-6-phosphate dehydrogenase

Summary This paper deals with the progress made over the last few years in our understanding of enzyme cytochemical staining methods as studied using a fundamental approach with the aid of a model system of thin gel films. Although model films with a matrix of polyacrylamide have been mostly used, the properties and possible applications of other matrices are also reviewed. The chemical aspects of the entrapment of enzyme molecules into a matrix are summarized. Special attention has been paid in model film studies to the principles of the trapping reaction of a diffusable precursor resulting from the enzymatic conversion of a substrate. They are considered here as they concern the cytochemical demonstration of acid phosphatase activity with a lead salt. The effect of fixatives on different enzyme activities, the diffusion rate of substrates and chromogenic compounds to the enzyme site, and enzyme kinetics under cytochemical conditions are also discussed, since they are factors which influence the final results of the staining procedures. The advantage of model film studies in enabling the direct correlation of cytochemical and biochemical results is outlined with special reference to the cytochemical determination of glucose-6-phosphate dehydrogenase with Tetra Nitro BT. A method for determining enzyme activities in the soluble fraction of isolated cells after incorporation in model films is described for the first time. This method has proved to be highly appropriate for microscopical observations of glucose-6-phosphate dehydrogenase activity in single cells, because it results in a good morphology and no formazan precipitaties outside the cells. On the other hand, this type of model film forms a bridge between fundamental model film studies using purified enzyme and quantitative enzyme cytochemistry performedin situ.     

Autoradiography-based cytochemical detection of ecto-ATPase, ecto-ADPase, 5′-nucleotidase, and extracellular adenosine production, employing 141Ce3+ as a capturing agent

Summary A method for the visualization of the ecto-nucleotidase enzyme activities present on the cell surface, employing¹⁴¹Ce³⁺ as a capturing and labelling agent, is described. Phosphate ions precipitated at the cell surface can be detected by coating the cells with an autoradiographic emulsion, followed by light microscopical inspection of the formed silver grains. The activities of ecto-ATPase, ecto-ADPase and 5′-nucleotidase were detected by this approach in four different cell lines. Parallel biochemical measurements of the activities of the corresponding enzymes were carried out in order to validate, evaluate, and optimize the cytochemical detection. The finding that Ce³⁺ ions are inhibitory to ecto-ATPase provided evidence for the necessity of carefully establishing appropriate reaction conditions for the cytochemical determination of ecto-nucleotidases. The application of this method to the indirect detection of extracellular adenosine production from substrates like ATP has also been documented. It allows a cytochemical determination of adenosine formed through cascade nucleotide dephosphorylation. This newly described method is of high sensitivity and potentially of value for a variety of applications, including not only cytochemistry but also cell biology, and molecular biology studies.     

A new generation approach in enzyme immobilization: Organic-inorganic hybrid nanoflowers with enhanced catalytic activity and stability

Many different micro and nano sized materials have been used for enzymes immobilization in order to increase their catalytic activity and stability. Generally, immobilized enzymes with conventional immobilization techniques exhibit improved stability while their activity is lowered compared to free enzymes. Recently, an elegant immobilization approach was discovered in synthesis of flower-like organic-inorganic hybrid nanostructures with extraordinary catalytic activity and stability. In this novel immobilization strategy, proteins (enzymes) and metal ions acted as organic and inorganic components, respectively to form hybrid nanoflowers (hNFs). It is demonstrated that the hNFs highly enhanced catalytic activities and stability in a wide range of experimental conditions (pHs, temperatures and salt concentration, etc.) compared to free and conventionally immobilized enzymes. This review mainly discussed the synthesis, characterization, development and applications of organic-inorganic hybrid nanoflowers formed of various enzymes and metal ions and explained potential mechanism underlying enhanced catalytic activity and stability.     

Indigogenic substrates for detection and localization of enzymes

Indoxyl esters and glycosides are useful chromogenic substrates for detecting enzyme activities in histochemistry, biochemistry and bacteriology. The chemical reactions exploited in the laboratory are similar to those that generate indigoid dyes from indoxyl-beta-d-glucoside and isatans (in certain plants), indoxyl sulfate (in urine), and 6-bromo-2-S-methylindoxyl sulfate (in certain molluscs). Pairs of indoxyl molecules released from these precursors react rapidly with oxygen to yield insoluble blue indigo (or purple 6,6'-dibromoindigo) and smaller amounts of other indigoid dyes. Our understanding of indigogenic substrates was developed from studies of the hydrolysis of variously substituted indoxyl acetates for use in enzyme histochemistry. The smallest dye particles, with least diffusion from the sites of hydrolysis, are obtained from 5-bromo-, 5-bromo-6-chloro- and 5-bromo-4-chloroindoxyl acetates, especially the last of these three. Oxidation of the diffusible indoxyls to insoluble indigoid dyes must occur rapidly. This is achieved with atmospheric oxygen and an equimolar mixture of K(3)Fe(CN)(6) and K(4)Fe(CN)(6), which has a catalytic function. H(2)O(2) is a by-product of the oxidation of indoxyl by oxygen. In the absence of a catalyst, the indoxyl diffuses and is oxidized by H(2)O(2) (catalyzed by peroxidase-like proteins) in sites different from those of the esterase activity. The concentration of K(3)Fe(CN)(6)/K(4)Fe(CN)(6) in a histochemical medium should be as low as possible because this mixture inhibits some enzymes and also promotes parallel formation from the indoxyl of soluble yellow oxidation products. The identities and positions of halogen substituents in the indoxyl moiety of a substrate determine the color and the physical properties of the resulting indigoid dye. The principles of indigogenic histochemistry learned from the study of esterases are applicable to methods for localization of other enzymes, because all indoxyl substrates release the same type of chromogenic product. Substrates are commercially available for a wide range of carboxylic esterases, phosphatases, phosphodiesterases, aryl sulfatase and several glycosidases. Indigogenic methods for carboxylic esterases have low substrate specificity and are used in conjunction with specific inhibitors of different enzymes of the group. Indigogenic methods for acid and alkaline phosphatases, phosphodiesterases and aryl sulfatase generally have been unsatisfactory; other histochemical techniques are preferred for these enzymes. Indigogenic methods are widely used, however, for glycosidases. The technique for beta-galactosidase activity, using 5-bromo-4-chloroindoxyl-beta-galactoside (X-gal) is applied to microbial cultures, cell cultures and tissues that contain the reporter gene lac-z derived from E. coli. This bacterial enzyme has a higher pH optimum than the lysosomal beta-galactosidase of animal cells. In plants, the preferred reporter gene is gus, which encodes beta-glucuronidase activity and is also demonstrable by indigogenic histochemistry. Indoxyl substrates also are used to localize enzyme activities in non-indigogenic techniques. In indoxyl-azo methods, the released indoxyl couples with a diazonium salt to form an azo dye. In indoxyl-tetrazolium methods, the oxidizing agent is a tetrazolium salt, which is reduced by the indoxyl to an insoluble coloured formazan. Indoxyl-tetrazolium methods operate only at high pH; the method for alkaline phosphatase is used extensively to detect this enzyme as a label in immunohistochemistry and in Western blots. The insolubility of indigoid dyes in water limits the use of indigogenic substrates in biochemical assays for enzymes, but the intermediate indoxyl and leucoindigo compounds are strongly fluorescent, and this property is exploited in a variety of sensitive assays for hydrolases. The most commonly used substrates for this purpose are glycosides and carboxylic and phosphate esters of N-methylindoxyl. Indigogenic enzyme substrates are among many chromogenic reagents used to facilitate the identification of cultured bacteria. An indoxyl substrate must be transported into the organisms by a permease to detect intracellular enzymes, as in the blue/white test for recognizing E. coli colonies that do or do not express the lac-z gene. Secreted enzymes are detected by substrate-impregnated disks or strips applied to the surfaces of cultures. Such devices often include several reagents, including indigogenic substrates for esterases, glycosidases and DNAse.     

Quantitative aspects of cytochemical methods for acetylcholinesterase studied with a cytochemical model system

A model system of polyacrylamide films containing the Triton extract of rat brain homogenate was applied to investigate quantitatively some aspects of three methods for the cytochemical demonstration of acetylcholinesterase activity (Lewis 1961; Karnovsky and Roots 1964; Tsuji 1974). Biochemical determinations showed that about 90% of the acetylcholinesterase activity originally present in the Triton extract were still detectable in the films. The relationship of the formation of cuprous thiocholine iodide in the case of the methods of Lewis (1961) or Tsuji (1974) and of cupric ferrocyanide at the reaction of Karnovsky and Roots (1964) to either enzyme concentration or incubation time were tested in detail. The results showed that for the method of Tsuji and, with some restrictions, also for the method of Karnovsky and Roots a linearity exists in these two respects. In the case of the Lewis technique, an approximate linearity between the amount of reaction product and incubation time could only be found from 90 min onward, but no linearity was detected in relation to the enzyme concentration. At low enzyme concentrations, too little white precipitate was formed in comparison to higher ones. Therefore it is suggested that this technique, as compared to the methods of Tsuji and Karnovsky and Roots, probably is less suitable as a quantitative cytochemical method.     

土壤食细菌线虫与细菌的相互作用及其对N、P矿化生物固定的影响及机理

采用悉生微缩体系,研究了４０ｄ 培养期内不添加外源基质条件下食细菌线虫（Ｐｒｏｔｏｒｈａｂｄｔｉｓ ｓｐ．）和细菌（Ｐｓｅｕｄｏｍ ｏｎａｓｓｐ．）的相互作用及其对Ｎ、Ｐ转化的影响。在种植及不种植小麦的土壤中,发现接种线虫后细菌数量显著增加,非根标土壤细菌的增加量又比根际土明显。在种植小麦体系中,根际与非根际土壤线虫均比不种作物体系有增加趋势,其中根际土壤线虫种群的提高尤为显著。只加细菌处理中土壤Ｎ、Ｐ均无净矿化,相反培养前期出现轻微的生物固定。线虫的引入显著提高了土壤矿质Ｎ、微生物量Ｎ 和微生物量Ｐ的含量,但对土壤有效Ｐ影响很小。这表明线虫活动主要是促进了Ｎ的矿化,而Ｐ表现出较强的生物固定。文中还分析了线虫捕食对细菌的增殖作用以及线虫——细菌相互作用在Ｎ、Ｐ矿化和生物固定中的机理。     

Mechanisms of metal-salt methods in enzyme cytochemistry with special reference to acid phosphatase

Summary This review is concerned with theoretical and experimental aspects of the factors governing the localizing potentialities of cytochemical enzyme reactions that are based on the metal-salt principle, that is, the precipitation of the primary product of the enzymatic reaction by a heavy-metal ion at the enzymatic site. Special attention is given to the lead phosphate precipitation process in acid phosphatase cytochemistry. The various model systems developed for the study of the factors involved in precipitation are described and their advantages and disadvantages discussed. Furthermore, the various cytochemical methods so far used for the demonstration of acid phosphatase activity are critically evaluated in the light of the results obtained with the model systems.     

A tetrazolium method for non-specific alkaline phosphatase

Summary A technique for the histochemical demonstration of non-specific alkaline phosphatase was developed using a medium containing indoxyl phosphate and a tetrazolium salt, Nitro B.T. The tetrazolium salt was reduced to diformazan by the hydrogen ions released by the formation of either indigo or indigo white by reaction of the enzyme on the indoxyl phosphate.The localization in the organs investigated was similar to that obtained by the standard azo dye and lead techniques.     

Ultrastructural localization of nucleic acids through several cytochemical techniques on osmium-fixed tissues: comparative evaluation of the different labelings

Several cytochemical techniques, such as sodium tungstate, acid hydrolysis phosphotungstic acid (HAPTA), ethylenediaminetetraacetic acid (EDTA), RNase-gold, and osmium-ammine, have been applied for the ultrastructural demonstration of nucleic acids on sections of tissues fixed in glutaraldehyde postfixed with osmium tetroxide and embedded in Epon. In order to obtain specific results, the sections had to be treated with sodium metaperiodate prior to performing the labeling protocol. The results for each method were identical to those obtained on nonosmicated tissues; the main difference being the enhancement in the ultrastructural preservation, which allowed for higher resolution. In addition to these techniques, and for comparative evaluations, DNA was also revealed by the DNase-gold approach on nonosmicated tissue sections. The consistency in the results, obtained over the nucleus with either EDTA or the RNase-gold complex for revealing RNA and those obtained with either osmium-ammine or DNase-gold for revealing DNA, supports the high specificity of the RNase-gold, DNase-gold, and osmium-ammine techniques. Furthermore, these results demonstrate the possibility of performing various cytochemical techniques on tissues processed for routine electron microscopy.     

Light and electron microscopic demonstration of sialic acid residues with the lectin from Limax flavus: a cytochemical affinity technique with the use of fetuin-gold complexes

The development of a cytochemical affinity technique for the demonstration of sialic acid residues by light and electron microscopy is reported. The lectin from the slug Limax flavus, with its narrow specificity for N-acetyl- and N-glycolylneuraminic acid, was applied to tissue sections. Subsequently fetuin-gold complexes were used to visualize the tissue-bound lectin. Different cytochemical controls, including sugar inhibition tests, neuraminidase digestion, the use of fetuin-gold complexes alone, or acid hydrolysis of sections, proved the specificity of the technique. Postembedding staining was performed on frozen, paraffin, or semithin resin sections for light microscopy and on thin sections from low temperature Lowicryl K4M-embedded material for electron microscopy. The distribution of sialic acid residues in rat pancreas, liver, and colonic mucosa was investigated.     

Cytochrome oxidase activity associated with the inside of the cytoplasmic membrane in swarm cells and sheath-forming cells of Sphaerotilus natans: an ultrastructural study using 3,3′-diaminobenzidine (DAB)

Cytochrome oxidase activity has been demonstrated by electronmicroscopical cytochemical methods in swarm cells as well as in the sheathforming cells of Sphaerotilus natans. This enzyme is associated with the inside of the cytoplasmic membrane. The conditions for demonstrating this cytoplasmic membrane-associated cytochrome oxidase differ from those enabling the demonstration of the cytochrome oxidase in the polar organelle of this bacterial species. The location of this enzyme also contrasted to that generally known from other bacteria and from mitochondria.     

CYTOCHEMICAL LOCALIZATION OF MALATE SYNTHASE IN GLYOXYSOMES

Cytochemical staining techniques for microbodies (peroxisomes) are limited at present to the enzymes catalase and α-hydroxy acid oxidase, and neither technique can distinguish glyoxysomes from other microbodies. Described here is a procedure using ferricyanide for the cytochemical demonstration by light and electron microscopy of malate synthase activity in glyoxysomes of cotyledons from fat-storing cucumber and sunflower seedlings. Malate synthase, a key enzyme of the glyoxylate cycle, catalyzes the condensation of acetyl CoA with glyoxylate to form malate and release free coenzyme A. Localization of the enzyme activity is based on the reduction by free CoA of ferricyanide to ferrocyanide, and the visualization of the latter as an insoluble, electron-opaque deposit of copper ferrocyanide (Hatchett's brown). The conditions and optimal concentrations for the cytochemical reaction mixture were determined in preliminary studies using a colorimetric assay developed to measure disappearance of ferricyanide at 420 nm. Ultrastructural observation of treated tissue reveals electron-opaque material deposited uniformly throughout the matrix portion of the glyoxysomes, with little background deposition elsewhere in the cell. The reaction product is easily visualized in plastic sections by phase microscopy without poststaining. Although the method has been applied thus far only to cotyledons of fat-storing seedlings, it is anticipated that the technique will be useful in localizing and studying glyoxylate cycle activity in a variety of tissues from both plants and animals.     

The demonstration of arylsulfatases with 4-nitro-1,2-benzenediol mono(hydrogen sulfate) by the formation of osmium blacks at the sites of copper capture.

A new method is described for the direct cytochemical demonstration of lysosomal arylsulfatases utilizing a synthetic substrate, 4-nitro-1,2-benzenediol mono(hydrogen sulfate), and a copper capture reaction. A small amount of Hatchett's brown (cupric ferrocyanide, Cu2Fe(CN)6-7 H2O) formed at the subcellular sites of copper capture is then utilized as a heterogeneous catalyst to effect the oxidative polymerization of 3,3'-diaminobenzidine which results in the formation of an insoluble, highly colored osmiophilic indamine polymer at the sites of enzymatic activity. The reaction product even at this stage prior to osmication is highly visible. It is readily seen with a light microscope in 50 mum sections of fixed tissues prepared with a mechanical chopper or in 10 micron cryostat sections treated for arylsulfatase activity. Upon osmication, an electron-opaque osmium black is formed which is much less soluble than the products of either the lead or barium capture reactions currently used for the demonstration of arylsulfatase with the electron microscope. The selection of areas of plastic-embedded tissues for ultrathin sectioning is facilitated by the ready visibility of these osmium black end products on 1-2 mum plastic sections which can be studied with the light microscope. This method gives permanent specimens demonstrating arylsulfatases A or B in lysosomes and autophagic vacuoles. In addition, enzyme activity is seen occasionally in the Golgi region or lamellae of certain cells believed to be elaborating sulfated products. In these instances, it may be demonstrating sulfotransferase activity.     

Spheroplast-derived membrane vesicles from Rhodobacter capsulatus cells catalyzing nucleotide transport

Rodobacter capsulatus cells, which were cultured anaerobically in high light intensity, had fewer foldings in the cytoplasmic membrane than those which were grown in lower light intensities. Spheroplast-derived membrane fractions obtained from cells cultured under high light intensity contained a high yield of large right-side-out membrane vesicles. The right-side-out vesicles catalyzed reversible light-induced proton efflux as did intact cells. Nucleotide transport activity was also catalyzed by these membrane vesicles. This activity was indirectly monitored by measurement of photophosphorylation or hydrolysis of externally added diphospho- and triphosphonucleosides. These enzymatic activities occur inside the cytoplasmic membrane of spheroplasts and membrane vesicles and therefore require the transport of the externally added reagents. The indirect measurements of transport were complemented by the demonstration of direct uptake of radiolabeled nucleotides into the membrane vesicles. These data support the suggestion that a nucleotide transporter located in the cytoplasmic membrane of R. capsulatus bacteria mediates these activities.     

Ultracytochemical detection of nucleoside phosphatase activity in human peripheral blood cells

The authors elaborated and described the optimum conditions for fixation, incubation and preparation of human blood cell samples in minimum quantities for ultrastructural and ultracytochemical investigations of 5'-nucleotidase and ATPase activities. The best preservation of the blood cell ultrastructure was obtained after fixation with buffered 1% glutaraldehyde solution followed by postfixation in buffered 1% OsO4 solution. The best ultracytochemical demonstration of 5'-nucleotidase and ATPase activities was achieved after fixation in buffered 2% formaldehyde prior to cytochemical incubation. DMSO added to either fixation or incubation media was shown to damage the plasmalemma and glycocalyx structure in cell suspensions. ATPase in 5'-nucleotidase activities were revealed in plasmalemma, cytoplasmic reticulum, Golgi complex, mitochondria and in the nuclei, in particular, in the perinuclear space, nucleolus and chromatin. With respect to the localization and activity of nucleosidephosphatases, lymphocytes proved to be most heterogenic, with the enzyme activity level directly depending on the rate of ultrastructural differentiation in lymphocytes.     

Cytochemistry of human catalase. The demonstration of hepatic and renal peroxisomes by a high temperature procedure.

The cytochemical demonstration of marker enzymes for subcellular organelles permits light microscopic analysis of their structure and function in normal and diseased tissues. Currently available staining procedures for the peroxidatic activity of catalase in peroxisomes of plant and animal cells yield weak and inconsistent light microscopic staining when applied to human tissues. We have developed a simple and sensitive high temperature procedure that clearly and reproducibly stains these abundant, but poorly understood, organelles in biopsy specimens of human liver and kidney. This method utilizes formaldehyde fixation, a modified diaminobenzidine (DAB) medium, incubation at 45 degrees C and postosmication for both light and electron microscopy.     

Quantitative aspects of cytochemical methods for acetylcholinesterase studied with a cytochemical model system

Summary A model system of polyacrylamide films containing the Triton extract of rat brain homogenate was applied to investigate quantitatively some aspects of three methods for the cytochemical demonstration of acetylcholinesterase activity (Lewis 1961; Karnovsky and Roots 1964; Tsuji 1974).Biochemical determinations showed that about 90% of the acetylcholinesterase activity originally present in the Triton extract were still detectable in the films. The relationship of the formation of cuprous thiocholine iodide in the case of the methods of Lewis (1961) or Tsuji (1974) and of cupric ferrocyanide at the reaction of Karnovsky and Roots (1964) to either enzyme concentration or incubation time were tested in detail. The results showed that for the method of Tsuji and, with some restrictions, also for the method of Karnovsky and Roots a linearity exists in these two respects. In the case of the Lewis technique, an approximate linearity between the amount of reaction product and incubation time could only be found from 90 min onward, but no linearity was detected in relation to the enzyme concentration. At low enzyme concentrations, too little white precipitate was formed in comparison to higher ones. Therefore it is suggested that this technique, as compared to the methods of Tsuji and Karnovsky and Roots, probably is less suitable as a quantitative cytochemical method.This word was performed while one of us (Dr. Andrä) was in receipt of a visitor grant from the Netherlands Organization for the Advancement of Pure Research (ZWO)     

Indoxyl alfa-D-galactoside as the temporarily last substrate for glycosidase histochemistry. The present state of the art in histochemical glycosidase research using indoxyl glycosidas

Initiated by the recently published histochemical method for the investigation of alfa-D-galactosidas with an indoxyl substrate, the current state of this group of synthetic compounds in light and electron microscopic histochemical glycosidase research is evaluated whereby historical, functional, methodological and applied aspects are considered. Beginning with the introduction of indoxyl acetate for non-specific esterase in 1951 and 1952 numerous other indoxyl substrates and mostly substituted in the 5- and 4-position of the indol ring by Br and Cl were developed to study histochemically non-specific phosphatases and glycosidases and frequently used in indigogenic, azoidoxyl, tetrazolium salts and metal salt techniques for catalytic (activity) histochemical and less often for immunohistochemical, affinity histochemical and hybridohistochemical purposes. The last substrate which became available and was validated for activity histochemistry was 5-Br-4-Cl-3-indoxyl alfa-1-galactoside for alfa-1-galactosidase. At present, the indoxyl glycosides are more widely used than 5-Br-4-Cl-3-indoxyl acetates and phosphates when compared with the alternative synthetic (artificial) naphthol, 6-Br-2-naphthol or ternative synthetic (artificial) naphthol, 6-Br-2-naphthol AS substrates, and among the indoxyl glycosides those for the oxoglycosidases lactase, maltase-glucoamylase, glucoamylase, acid beta-D-galactosidase, neuroaminidase and alfa-D-galactosidase are superior to other artificial compounds. When one considers in addition, electron microscopic catalytic glicosidase histochemistry (ultracytochemistry, 5-Br-4-Cl-3-indoxyl is the only suitable moiety for this purpose. These glycosidase can mostly be localized in plasma membranes or lysosomes and also measured there in tissue sections but are also found in secretion granules, endoplasmic reticulum and organ lumina.